KR20150022226A - Granule ice maker for ice water - Google Patents

Abstract

The present invention relates to an iced granule maker for ice water, comprising: a cylindrical cooling housing (10) having a cooling coil (9-1) immersed in an antifreeze solution (11); a rotation unit (20) installed in a space under the cylindrical cooling housing (10) outside the cylindrical cooling housing (10); a nozzle part (30) installed in the outer cylindrical wall (13) of the cylindrical cooling housing (10) to inject water or liquids; a blade part (40) integrated with the nozzle part (30) to rake out the iced water or liquids which have passed through the nozzle part (30) on the outer cylindrical wall (13); and a bracket (50) which supports the blade part (40) and the nozzle part seated on the outer cylindrical wall (13) of the cylindrical cooling housing (10) which supports the cylindrical cooling housing (10) to be rotated using the rotation unit (20). The purpose of the present invention is to provide an ice water maker to make ice to enable users to instantly make ice water using ice and additives.

Description

{Granule ice maker for ice water}

The present invention relates to a fine granular ice maker.

In general, an ice maker is known in which a predetermined size of ice is purchased, and ice collected by the ice blasting blade is collected and used as ice water (Korean Patent Registration No. 10-1029373). However, It is troublesome to do.

In order to achieve this, a technology capable of being used as icing water by making ice itself was developed as a domestic patent registration No. 10-0734481. However, since the construction is complicated, there is a factor of cost increase and ice is required to be frozen. The trend was not fit.

It is an object of the present invention to provide an ice water maker which can make ice water by itself to produce ice water and which can be eaten directly by using an additive.

Another object of the present invention is to provide an ice water maker in which the nozzle bracket for freezing ice is inclined longitudinally on the outer surface of the cooling cylindrical housing to freeze the thickness of the ice up and down uniformly.

Another object of the present invention is to provide a cooling cylinder housing having a blade body for scraping frozen ice on the outer surface of the cooling cylindrical housing in the form of granules or snow flakes to make ice water on the outer surface of the cooling cylinder housing, So that it can be scratched without being caught by the ice maker.

To this end, the present invention provides a cooling device comprising: a cooling cylindrical housing in which a cooling coil is immersed in an antifreeze;

Rotation means provided on an outer bottom surface of the cooling cylindrical housing;

A nozzle unit installed on an outer cylindrical wall of the cooling cylindrical housing to inject water;

A blade portion integrally provided with the nozzle portion, the water passing through the nozzle portion scraping the frozen ice from the outer cylindrical wall; And

And a bracket for supporting the nozzle portion and the blade portion placed on the outer cylindrical wall of the cooling cylindrical housing and supporting the cooling cylindrical housing by using the rotating means.

As described above, the present invention provides an ice water maker that allows ice to be produced by itself to produce ice water, and which can be eaten directly by using an additive.

The present invention provides an ice water maker in which the nozzle bracket for freezing ice is inclined longitudinally on the outer surface of a cooling cylindrical housing, so that the thickness of ice is frozen up and down uniformly.

The present invention relates to a cooling cylinder housing having a blade body for scraping frozen ice on the outer surface of the cooling cylinder housing in the form of granules or snow flakes to make ice water. The cooling body is provided on the outer surface of the cooling tube housing so as not to overload the ice- And an ice maker for scraping ice.

1 is a cooling cycle principle of the present invention,
FIG. 2 is a perspective view showing the cooling cylinder housing of the present invention filled with an antifreeze and the cooling coil being immersed therein,
FIG. 3 is a configuration example showing the operation principle of the present invention,
Fig. 4 is a perspective view of the main part of the present invention,
FIG. 5 is a perspective view showing the installation of the cooling cylindrical housing of the present invention,
6 is a sectional view taken along the line AA in Fig. 5,
7 is a block diagram of the control block of the present invention.

FIG. 1 is a refrigerating cycle diagram for explaining the principle of a micro granulated ice maker for ice water according to the present invention, compressing a refrigerant gas in a compressor 2 and discharging the compressed high temperature and high pressure refrigerant gas, The refrigerant gas passes through the water-cooled condenser (4), thereby releasing heat to the outside of the condenser (4), and is converted into a liquid phase of high temperature and high pressure.

Further, the refrigerant is again converted into low-temperature low-pressure liquid through the dryer 6 and the expansion valve 8, and the low-temperature low-pressure liquid flows into the water-cooled evaporator 9. At this time, the evaporator 9 takes cold heat from the refrigerant and freezes.

Therefore, after the compressor 2 is compressed, the refrigerating apparatus is circulated through the circulation cycle of the condenser 4, the expansion valve 8, the evaporator 9, and the compressor 2.

The embodiment of the present invention, which can be illustrated in FIGS. 2 to 7, includes a cooling cylindrical housing 10 in which a cooling coil 9-1 is immersed in an antifreeze 11;

A rotation means (20) provided on an outer bottom surface of the cooling cylindrical housing (10);

A nozzle part (30) provided on the outer cylindrical wall (13) of the cooling cylindrical housing (10) for spraying water;

A blade part 40 integrally provided with the nozzle part 30 and scraping the ice that has passed through the nozzle part 30 from the outer cylindrical wall 13; And

A nozzle unit 30 and a blade unit 40 supported on an outer cylindrical wall 13 of a cooling cylindrical housing 10 and supporting a rotating cylindrical housing 10 using a rotating means 20 50).

The nozzle portion 30 and the blade portion 40 are configured to be fixed to the bracket 50 in an inclined manner in the longitudinal direction on the outer cylindrical wall 13 of the cooling cylindrical housing 10. The rotating means 20 may be provided on the outer upper surface of the cooling cylindrical housing 10.

The cooling cylinder 9-1 is accommodated in the cooling cylindrical housing 10 and the accommodated cooling coil 9-1 is connected to the compressor 2, the condenser 4, the dryer 6, the expansion valve 8, And the cooling coil 9-1 is also a coil for moving the refrigerant to perform the function of the evaporator 9 in the heat exchange cycle circulated to the evaporator 9. The cooling coil 9-1 is also connected to the bracket 50 through the inlet .

The inlet and outlet a and b are supported by a bracket 50 via a lid 10a which is joined to the upper end of the cooling cylinder 10 in a cohesive state and the lid 10a is supported by a bracket 50, And is fixed with a fixing screw 53.

3 is a configuration diagram showing an embodiment of the present invention. The water container 37 and the liquid raw material containers 38 and 39 are provided at the upper position inside the outer housing 1 and the water clearance 37-1 is provided at the lower portion. , A raw material pipe (38-1), and a raw material pipe (39-1) are installed to control the transfer to the valve (32-1). A compressor 32-2 is provided on the outlet side of the valve 32-1 so that the main pipe 32 is connected to the water supply pipe 37-1, the raw material pipe 38-1, the selected contents of the raw material pipe 39-1 To be conveyed at a high pressure.

The nozzle bracket 36 and the blade portion 40 are supported on the outer peripheral surface of the cooling cylindrical housing 10 by a bracket 50 (not shown in FIG. 3) in an inclined longitudinal direction. Additive material containers 1a, 2a and 3a are provided on the side surfaces of the cooling cylindrical housing 10 and the respective containers are connected to the discharge pipes 1a-1, 2a-2 through the valves 1a-2, 2a- 1 a and 1 a and 1 a are installed at the lower ends of the discharge pipes 1 a - 1, 2 a - 1, and 3 a - 1, The collection space 3 is formed in the lower part of the outer housing 1. [

7 is a block diagram of the control block of the present invention. The control unit 61 is implemented using a microcomputer. The power source is provided through a rectifying unit 63 for rectifying AC power to DC power. The other output stage P1 controls the refrigerant driving unit 65 for driving the compressor 2 shown in Figure 1 and the other output stage P3 controls the motor driving unit 62 for driving the motor M1, Controls the valve 32 shown in Fig. 3, and the other output terminal P4 connects to the compressor driving unit 32-3 that drives the compressor 32-2 shown in Fig.

2, the refrigerant passes through the cooling coil 9-1 constituting the evaporator 9 performing the refrigeration cycle shown in FIG. 1, and absorbs heat, thereby changing the antifreeze around the refrigerator to zero. 3) to the outside cylindrical wall 13 around the side surface of the cooling cylindrical housing 10 as shown in FIG. 3 or the liquid raw material bottles 38 and 39, Is supplied to the nozzle bracket 36 through the main pipe 32 under pressure through the compressor 32-2 at the same time as the selection of the cooling coil 32-1, 1 is immersed in the antifreeze 11, the cold air is uniformly transmitted to the outer cylindrical wall so as to freeze ice of a uniform thickness. Preferably, when the cooling unit 10 makes one revolution, It is preferable to set the cooling efficiency so as to use the ice.

In this case, it is preferable that the nozzle bracket 36 be inclined in the outer circumferential direction of the cooling cylindrical housing 10 as shown in FIG. 3 so that the nozzle bracket 36 does not vertically overlap the injection liquid through the adjacent nozzle So as to obtain a constant thickness of ice. As shown in FIG. 4, the sprayed liquid through the plurality of nozzle tubes 34 installed at regular intervals in the vertical direction in the main tube 32 maintains a desired thickness through the vertical spacing and vertical tilting, and prevents the spray liquid from flowing down do. In this case, if the separation distance d is set at a preferable distance as shown in FIG. 4, the thickness of the ice can be optimized according to the rotation speed and the degree of the sprayed liquid.

Frozen ice in the outer cylindrical wall 13 of the cooling cylindrical housing 10 is peeled off by the blade portion 40. 5 and 6, the rotation shaft 25 integrally projects from the bottom of the bottom of the cooling cylindrical housing 10 and the upper portion of the rotation shaft 25 is integrally formed with the lower bracket 52 via the bearing 51 And the lower portion of the rotating shaft 25 is provided with a pulley 23 to receive the power from the pulley 22 of the motor 21 through the pulley belt 24. As shown in Fig. 7, when the power switch 64 is turned on, the rotational force of the motor 21 rotates the cooling cylindrical housing 10 in the direction of the arrows in Fig. 3 and Fig. In this case, as shown in Fig. 6, the lid 10a is fixed by the lid fixing screw 53 at the upper part of the bracket 50, and the lid 10a and the cooling cylinder 10 mutually coalesce through the bearing 10b The inlet 10a of the cooling coil 9-1 is supported by the lid 10a so that the cooling coil 9-1 is fixed and the rotational force through the rotation axis 25 is transmitted to the cooling cylinder 10, . The blade portion 40 is formed such that the blade 42 abuts on the outer cylindrical wall 13 before the ice is free and the curved surface 43 contacts the surface of the outer cylindrical wall 13 coaxially, It provides a bearing to prevent ice from separating. In addition, since the blade 42 is tilted so as to be inclined to the vertical length of the outer cylindrical wall 13, it acts to disperse a large amount of force which is initially applied to cut and separate ice, (5).

If one or more of the desired additive material containers 1a, 2a, 3a are selected and opened by an instruction through the output stage P5 as required, as shown in FIG. 6 and FIG. 5, 2a-1, 3a-1), it is possible to prepare the ice water according to the taste of the desired menu and eat it.

1, an outer housing 1a, 2a, 3a, an additive material container 1a-1, 2a-1, 3a-1, a discharge pipe 1a-2, 2a-2, 3a-2, a valve 2, a compressor 3, A cooling cylinder housing 11, an antifreeze 13, a cooling cylinder wall 20, a rotation means 21, a motor 22, a pulley 23, a pulley 24, a pulley belt 25 A nozzle 32, a valve 32-2, a compressor 34, a nozzle tube 36, a nozzle bracket 37, a water bottle 37-1, a water discharge tube 38, a liquid fuel tank 38-1, a raw material pipe 39, a liquid The fuel cell according to any one of claims 1 to 3,

Claims (4)

A cooling cylindrical housing 10 in which a cooling coil 9-1 is immersed in the antifreeze 11;
A rotation means (20) provided outside the cooling cylindrical housing (10);
A nozzle part (30) provided on the outer cylindrical wall (13) of the cooling cylindrical housing (10) for spraying water;
A blade part 40 integrally provided with the nozzle part 30 and scraping the ice that has passed through the nozzle part 30 from the outer cylindrical wall 13; And
A nozzle unit 30 and a blade unit 40 supported on an outer cylindrical wall 13 of a cooling cylindrical housing 10 and supporting a rotating cylindrical housing 10 using a rotating means 20 50). ≪ / RTI >
The ice making machine according to claim 1, wherein the nozzle unit (30) and the blade unit (40) are fixed to the bracket (50) in an inclined manner in the longitudinal direction on the outer cylindrical wall (13) of the cooling cylindrical housing Granule ice maker.
A cooling coil (9-1) is accommodated in a cooling cylindrical housing (10), and the accommodated cooling coil (9-1) is connected to a compressor (2), a condenser (4), a dryer The cooling coil 9-1 is also a coil through which the refrigerant moves to perform the function of the evaporator 9 in the heat exchange cycle circulated to the evaporator 9, the expansion valve 8 and the evaporator 9. The cooling coil 9-1 also enters the bracket 50, And the outlet (a, b) is supported.
The apparatus as claimed in claim 3, wherein the inlet and outlet (a, b) are supported on a bracket (50) via a lid (10a) 50) with a lid fixing screw (53).

Images